Wildland Fire and Soils - School of Forest Resources...
Transcript of Wildland Fire and Soils - School of Forest Resources...
Presentation Outline Southern Fire Exchange Introduction How does fire impact soils?
▪ Soil Heating ▪ Erosion Concerns ▪ BAER ▪ Hydrophobic Layer Formation ▪ Effects on SOM ▪ Effects on Soil N ▪ Effects on Soil P ▪ Carbon cycling and fire ▪ Biochar and Terra Preta ▪ Hydric Soils and Smoke
Stuff we don’t know about fire and soils
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Soil Heating
Fire impacts soils by transferring heat downward into soils. Heat flux to soils is MUCH
LESS than heat released aboveground.
8-10% (maximum of 25%) of
heat is transmitted downward to the soil
–Adapted from Kennard, D. Fire Ecology, available at: http://www.wildfirelessons.net
Heat transfer processes to soils: Radiation and convection: responsible for
most heat transfer from light fuels to soil.
Conduction important in heavy fuels (duff, organic soils, and slash piles)
Vaporization and condensation: water moves much faster through soil pores as a vapor and releases heat when it condenses.
The degree of soil heating is highly
variable and depends on: Fuel characteristics: loading, size,
arrangement, moisture content
Fire behavior: rate of spread, flame length, intensity, duration
Litter layer: thickness, packing,
moisture content, and
Soil properties: texture, organic content, moisture content
Notice the temperature differences between fire types and litter / soil depths!
High Intensity Wildfire in Ponderosa Pine Low Intensity Prescribed Fire in Ponderosa Pine
DeBano et. al 1998
How do you think the fuels and fire behavior influenced soil heating?
Wade Tract, GA Juniper Prairie Wilderness, FL
Surface layers and upper horizons are most influenced by heating.
As depth increases impacts of soil heating decrease.
Highly spatially variable due to fuels, fire behavior, residence time, and soil conditions (see prev. photos).
From Whelan, 1995
Temp. between 220ºC and 460ºC
combusts soil organic matter. This releases nutrients but can destroy soil structure. Long-term impact in systems where organic matter inputs are slow (arid environment).
Temp. > 460ºC alters clays & changes carbonate structure. Irreversible changes: soil is less plastic, less porous, less elastic, and highly erodible.
Elevated soil temperatures can kill soil microbes, plant roots, and seeds; destroy soil
organic matter; and alter soil nutrient and water status.
Effects of different soil temperatures on soil properties
–Adapted from Kennard, D. Fire Ecology, available at: http://www.wildfirelessons.net
Surface material consumption
Increased soil temp. due to insolation
Decreased SOM input
Increased erosion potential
–Adapted from Kennard, D.
Soil biota mortality / injury
Altered soil microbial populations
Altered soil fungal populations
Possible changes in nutrient / carbon cycling
Possible changes in decomposition rates
Soil erosion: transport of soil by water and wind.
Sediment: eroded soil carried to stream channels.
Sedimentation: deposition of sediment.. Susceptibility of soils to erosion is influenced by:
Soil Properties (course soils more erodible) Topography (higher on steep slopes) Vegetative cover (protection) Land use (large machinery, grazing) Climate (high rainfall following burns)
Surface erosion: Fire can increase surface erosion by: Removing cover (litter, vegetation) Loss of stabilizing root systems Consuming SOM Creating hydrophobic soils Soil mass movement: Fire can increase mass soil
movement (i.e. landslides, debris flows) Often following periods of high rainfall, after a fire
and prior to vegetation recovery Associated with steep slopes and high severity fires
This erosion of a drainage created an incised channel after the Cerro Grande Fire near Los Alamos, NM. The view is upstream and the blue backpack is about 1 meter tall. The maximum 30-minute rainfall intensity was about 20 mm/h. The incision seen in this photo was after the wildfire and rain storm; prior to the storm this drainage had no definite banks. Photo by John A. Moody
Video of post-fire (Waldo Canyon) flooding in Manitou Springs, Colorado:
http://www.youtube.com/watch?v=Etj1Z4nLeEo
“Burned Area Emergency Response” Program Interagency Organization BAER is “first aid” – immediate stabilization
that often begins before a fire is fully contained.
BAER objectives are to:
Alleviate emergency conditions to help stabilize soil; control water, sediment and debris movement; prevent impairment of ecosystems; mitigate significant threats to health, safety, life property and downstream values at risk.
Monitor emergency treatments.
BAER teams often develop early first-order fire effects maps for soil stabilization response programs
2013 Table Rock Fire Pisgah NF, North Carolina
2013 Hopkins Prairie Fire Ocala NF, Florida
BAER Mulch / Straw Treatments Heli-Mulching:
http://youtu.be/zrjBZ8RM3Ow?t=1m7s
BAER Video from NPS:
http://www.youtube.com/watch?v=BLB8QojgVbw
Can form following soil heating
Result: Water infiltration is limited (degree varies) http://geography.swansea.ac.uk/hydrophobicity/soil_hydrophobicity.htm
Influenced by vegetation, litter and duff accumulation, fire intensity and duration of heating
Believed to be caused by volatilization and condensation of organic compounds
Depth and thickness of hydrophobic layer varies
Duration of layer Prescribed Fire < 1yr
Wildfire > Several Years
Organic soils are different due to their potential to combust
High-moisture, low-oxygen, smoldering combustion can release high amounts of carbon, smoke, heat
Can last for days, months, years!
High heating of the soil can result in the alteration or consumption of soil organic matter (SOM).
SOM destruction begins at 200ºC and is complete at 500ºC;
SOM content usually highest in upper horizons
Why care about SOM?
SOM holds sand, silt, and clay particles into aggregates.
Loss of SOM = Loss of soil structure
Decreased SOM = Increased soil bulk density and reduced soil porosity
SOM important for carbon and nutrient cycling = soil quality / health
Nitrogen (N) Fire can have significant impacts on soil N.
Due to relatively low N volatilization temperatures
Fire can volatilize available N in the litter, vegetation, and upper horizons resulting in net system losses.
Ash deposition, incomplete combustion, and post-fire colonization by N fixing early successional legumes can lead to near-term recovery and pulses
Nitrogen Concentration Nitrogen Pool
Prescribed Fire Impacts on Nitrogen Pool at the Austin Cary Forest
(From Lavoie et al. 2010)
Phosphorous (P) Fire tends to have little
negative impact on soil P
Due to very high P volatilization temp
Fire can increase soil available P via ash deposition and incomplete combustion residue
Phosphorous Concentration Phosphorous Pool
Prescribed Fire Impacts on Phosphorous Pool at the Austin Cary Forest
(From Lavoie et al. 2010)
Above Ground Biomass
(ACF) 8,084 g C m-2
Powell et al. 2008
NEP = 192 g C m-2 (2000-2001)
Fire C Fdist* (ACF)
3860 g C m-2
Lavoie et al. 2010
*Fire occurred In 2003
GEP (ACF)
1794 g C m-2 yr -1
Powell et al. 2008
Rs = Ra+Rh
(N Florida) 1,179 g C m-2 yr-1
Ewell et al. 1987
Re
(ACF) 1602 g C m-2 yr -1
Powell et al. 2008
Forest Floor Biomass
1,780 g C m-2
Ewell et al. 1987
SOM / SOC 8,550 g C m-2
Ewell et al. 1987
Flateral
(Unknown)
Think: Carbon Pools and Fluxes Pool = Reservoir Flux = Movement
Soil carbon pools are usually unlikely to change in response to individual fires
Prescribed Fire Impacts on Carbon Pools at the Austin Cary Forest
(From Lavoie et al. 2010)
Carbon Concentration Carbon Pool
Long-term prescribed fire experiments have shown little impact on Southeastern soil carbon pools
Prescribed Fire Impacts on Carbon Pools at the Austin Cary Forest
(From K. Robertson Presentation 2009)
Soil Carbon Fluxes
Soils regularly emit (a flux) CO2 in a process known as soil respiration or soil CO2 efflux
Image from Woods Hole Research Center http://www.whrc.org/new_england/forest_ecol.htm
Soil respiration represents 50-60% of total ecosystem carbon budgets
Globally, soil respiration contributes an estimated 75 Pg C yr-1 to atmosphere (while fossil fuel burning contributes 6 Pg C yr-1)
Image from Woods Hole Research Center http://www.whrc.org/new_england/forest_ecol.htm
Rs = Ra + Rh
In temperate forests soil respiration is derived primarily from two main sources: Autotrophic sources of
CO2 (Ra)
Heterotrophic sources of CO2 (Rh)
Image from Woods Hole Research Center http://www.whrc.org/new_england/forest_ecol.htm
Autotrophic sources of CO2 (Ra)
Plant Roots Rhizosphere Fungi
Heterotrophic sources of CO2 (Rh)
Microbial aerobic respiration
Fungal Hyphae
http://www.rhizosystems.com/ J.P. Martin, et al., eds. SSSA, Madison, WI
Soil Streptomyces Bacteria
Factors shown to influence soil respiration Soil Temperature
Soil Moisture
Soil Physical Properties
Surface Vegetation Characteristics
Soil Surface Characteristics (duff/litter)
Image from Woods Hole Research Center http://www.whrc.org/new_england/forest_ecol.htm
Factors shown to influence soil respiration Soil Temperature
Soil Moisture
Soil Physical Properties
Surface Vegetation Characteristics
Soil Surface Characteristics (duff/litter)
Does fire influence these factors?
Study questions ▪ How do long-term
prescribed fire management regimes influence old-field soil respiration rates?
▪ How do biotic and abiotic factors including soil temperature, soil moisture, monthly precipitation, and stand characteristics affect soil CO2 efflux?
“Red Hills” of N. FL and S. GA 2,400 km2 region
Over 1,220 km2 in private hunting estates
Managed with freq. prescribed fire
Important as: ▪ Critical habitat for Red-cockaded
woodpecker, gopher tortoise, and 62 other T/E species
▪ Remnant longleaf pine forests and native groundcover
▪ Habitat for regionally declining Northern Bobwhite Quail
Tall Timbers Research Station (TTRS) Est. 1958
Leon County, Florida
Former quail hunting plantation
Prior to that it was farmed for cotton
1,600 ha of ‘old field’ pine dominated uplands
Site of the historic Herbert Stoddard Sr. Fire Ecology Research Plots (est. in 1960s)
Annually Burned (1YR) Biennially Burned (2YR) Fire Excluded Sites (40YR)
Stoddard Fire Research Plots:
L. Neel H. Stoddard
Overstory
Open canopy
Loblolly pine (Pinus taeda)
Shortleaf pine (Pinus echinata)
Midstory Open
Understory Dense oaks, grasses, herbs, shrubs
Shallow duff/litter layer
Fire
Frequent low intensity (March / April)
Burns understory veg. and litter
Play Stoddard Plot 1YR Video: http://www.youtube.com/watch?v=fpP9IDF-
qo0
Overstory
Closed canopy
Loblolly pine (Pinus taeda)
Shortleaf pine (Pinus echinata)
Sweet Gum(Liquidambar styraciflua)
Hickory (Cary tomentosa)
Midstory / Understory Sapling hardwoods, herbs, shrubs
Deep duff / litter layer
Fire
Excluded since 1960s
Fire Excluded (40YR)
Study Equipment LI-8100, Li-Cor Biosciences, Lincoln
NE Infared Gas Analyzer (IRGA) to detect CO2
concentrations.
8100-103 Model 20 cm Survey Chamber
Decagon Systems EC-5 Soil Moisture Probe
Omega 88311 E T-Handle Soil Temperature Probe
Study Design Three prescribed fire treatments
1YR, 2YR, 4oYR(Long-unburned)
Three replicates of each treatment (1YR-a, 1YR-b, 1YR-c) (2YR-a, 2YR-b, 2YR-c) (40YR-a, 40YR-b, 40YR-c)
Each replicate plot consisted of nine
sampling points in a 3 x 3 grid with 5m separation
Each plot sampled once every four
weeks Three times over the course of a day
(~0800-2000).
Plot vegetation sampled (BA, TPH, Litter, Duff)
Sampling Grid
5 m
5 m (20 cm soil collar sampling point)
Measured Variables
Soil CO2 Efflux Rate (μmol CO2 m-2 s-1)
Soil Temperature (⁰C)
Soil Moisture (m3/m3)
1YR = 1069 g m-2 yr-1
2YR = 1268 g m-2 yr-1
40YR = 1688 g m-2 yr-1
Estimated Monthly Soil C Efflux Est. Annual Soil C Efflux
• Monthly total C flux calculated using treatment specific
lin reg models of Rs response to air temperature (following Samuelson et al. (2004))
• Hourly air temperature from Aug 2009 – Jul 2010 from
Quincy FAWNS station used as input
Annual 40YR soil C
efflux was 37% and
25% higher than 1YR
and 2YR
Supporting evidence in freq. burned Stoddard Plots shows prescribed fire reducing carbon cycling and increasing C turnover time
(From K. Robertson Presentation 2009)
In loblolly-shortleaf pine old-field forests of North Florida:
A management regime of frequent prescribed fire (annual and biennial burning) results in lower soil respiration rates /annual soil C emissions than one of fire exclusion.
A prescribed fire management regime appears to slow carbon cycling in old-field sites, while the absence of fire leads to increased soil carbon decomposition and carbon cycling.
Study Conclusions
Biochar or “Terra Preta”
A stable form of carbon (think charcoal)
Created from incomplete organic matter combustion (low oxygen environment)
Biochar molecular structure facilitates nutrient retention (i.e. increased soil CEC)
Photo WikiPedia
Terra Preta Soil Oxisol
Terra Preta (trans: black earth) famous in the Brazilian Amazon region
Believed to be evidence of large past civilization / agriculture in region now dominated by tropical forest
Terra Preta believed to be an intentional soil amendment to increase soil nutrient retention (increased CEC) in a region with poor soils.
Why? Increased CEC = Better Plant Growth = More Food
Photo by Michael Palace
Recent research demonstrates significant increase in soil / plant productivity following bio char amendments. (Biederman and Harpole, 2012)
http://onlinelibrary.wiley.com/doi/10.1111/gcbb.12037/full
Techniques developed to identify critical
temperature / O2 thresholds for the formation of bio char.
Issues remain for “scaling-up” biochar production at the industrial level.
Why Biochar Today? Increased cost of
industrial fertilizers
Demand for food production given global population growth
Stable and low-cost / possibly profitable carbon sequestration technique
Photo UC Davis BioChar Project
“Isn’t fire like growing cows or corn? Don’t we have it figured out by now?”
– North Florida Prescribed Fire Council Attendee
Increased use of fuels mastication treatments
Reduce wildfire behavior
Prepare long-unburned sites for prescribed fire
Recently Treated Flatwoods
How well do prefire treatments and fire “surrogates” maintain ecosystem / soil processes over time?
Can we “masticate” our way out of WUI fire problems while maintaining functioning fire dependent ecosystems?
What are the best strategies for ecosystem / soil carbon retention?
Mature tree retention via forest “restoration” projects?
Stoddard-Neel forestry practices?
How will soil carbon and nutrient cycles respond to changes in climate and changes in disturbances (ie fire)?
Example: Changes in NPP following Duke Forest FACE (Free-Air CO2 Enrichment) experiment
Insert Duke Face photo
How will change in fire regimes (fire frequency and severity) alter soil carbon pools and fluxes in boreal forests and subarctic regions?
What about fire mediated methane (CH4) fluxes in these regions?
“Wildland Fire in Ecosystems: Effects on Soil and Water” (JFSP/USFS GTR)
Whelan, 1995 “The Ecology of Fire”
DeBano, 2000 “The Role of Fire and Soil Heating on Water Repellency”
Certini 2005 “Effects of Fire on Properties of Forest Soils: A Review”
Neary et. Al 2000 “Fire Effects on
Belowground Sustainability: A Review and Synthesis
David R. Godwin, Ph.D. Program and Outreach Coordinator Southern Fire Exchange University of Florida Email: [email protected] Twitter: @ThatFireSciGuy Web: http://www.davidrgodwin.com Southern Fire Exchange: http://www.southernfireexchange.org